In situ forming bone substitute materials are attractive candidates for filling irregularly shaped defects. In this study, a chemically modified form of the Pluronic (R) F127 hydrogel was used. Similar to the parent form, this derivative underwent a sol-gel transition in the body and additional radical curing resulted in a stable three-dimensional network gel with a controllable degradation rate. An extra cell source of autologous bone marrow-derived mesenchymal stem cells was mixed with the hydrogel to increase the ossification process, when implanted in noncritical size unicortical tibia defects. These cells were cultured and predifferentiated on two types of cell carrier systems, that is, gelatin CultiSpher-S (R) microcarriers and hydroxyapatite tubular carriers. Radiographic and histological evaluation revealed that bone regeneration was comparable in the defects with the bone substitute compositions and the untreated control defects at 2 and 4 weeks postimplantation and that newly formed bone originated from the cells on the CultiSpher-S carriers. This resulted, 6 and 8 weeks postimplantation, in faster bone repair in the defects filled with the hydrogel plus CultiSpher-S carriers in comparison to the control defects. Surprisingly, there was no formation of new bone originating from the hydroxyapatite carriers. The hydrogel by itself seemed to stimulate the natural repair process.

@article{872348,
abstract = {In situ forming bone substitute materials are attractive candidates for filling irregularly shaped defects. In this study, a chemically modified form of the Pluronic (R) F127 hydrogel was used. Similar to the parent form, this derivative underwent a sol-gel transition in the body and additional radical curing resulted in a stable three-dimensional network gel with a controllable degradation rate. An extra cell source of autologous bone marrow-derived mesenchymal stem cells was mixed with the hydrogel to increase the ossification process, when implanted in noncritical size unicortical tibia defects. These cells were cultured and predifferentiated on two types of cell carrier systems, that is, gelatin CultiSpher-S (R) microcarriers and hydroxyapatite tubular carriers. Radiographic and histological evaluation revealed that bone regeneration was comparable in the defects with the bone substitute compositions and the untreated control defects at 2 and 4 weeks postimplantation and that newly formed bone originated from the cells on the CultiSpher-S carriers. This resulted, 6 and 8 weeks postimplantation, in faster bone repair in the defects filled with the hydrogel plus CultiSpher-S carriers in comparison to the control defects. Surprisingly, there was no formation of new bone originating from the hydroxyapatite carriers. The hydrogel by itself seemed to stimulate the natural repair process.},
author = {Lippens, Evi and Vertenten, Geert and Giron{\`e}s Molera, Jordi and Declercq, Heidi and Saunders, Jimmy and Luyten, J and Duchateau, Luc and Schacht, Etienne and Vlaminck, Lieven and Gasthuys, Frank and Cornelissen, Maria},
issn = {1937-3341},
journal = {TISSUE ENGINEERING PART A},
keyword = {CULTURE,RATS,HYDROXYAPATITE,SCAFFOLD,ANIMAL-MODELS,VIVO,MACROPOROUS GELATIN SPHERES,ALLOGRAFT,GRAFT SUBSTITUTES},
language = {eng},
number = {2},
pages = {617--627},
publisher = {MARY ANN LIEBERT INC},
title = {Evaluation of Bone Regeneration with an Injectable, In Situ Polymerizable Pluronic (R) F127 Hydrogel Derivative Combined with Autologous Mesenchymal Stem Cells in a Goat Tibia Defect Model},
url = {http://dx.doi.org/10.1089/ten.tea.2009.0418},
volume = {16},
year = {2010},
}